// Copyright 2013 The Chromium Authors // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "url/url_canon_internal.h" #include #include #include #ifdef __SSE2__ #include #elif defined(__aarch64__) #include #endif #include #include #include "base/bits.h" #include "base/numerics/safe_conversions.h" #include "base/strings/utf_string_conversion_utils.h" #include "url/url_features.h" namespace url { namespace { // Find the initial segment of the given string that consists solely // of characters valid for CHAR_QUERY. (We can have false negatives in // one specific case, namely the exclamation mark 0x21, but false negatives // are fine, and it's not worth adding a separate test for.) This is // a fast path to speed up checking of very long query strings that are // already valid, which happen on some web pages. // // This has some startup cost to load the constants and such, so it's // usually not worth it for short strings. size_t FindInitialQuerySafeString(const char* source, size_t length) { #if defined(__SSE2__) || defined(__aarch64__) constexpr size_t kChunkSize = 16; size_t i; for (i = 0; i < base::bits::AlignDown(length, kChunkSize); i += kChunkSize) { char b __attribute__((vector_size(16))); memcpy(&b, source + i, sizeof(b)); // Compare each element with the ranges for CHAR_QUERY // (see kSharedCharTypeTable), vectorized so that it creates // a mask of which elements match. For completeness, we could // have had (...) | b == 0x21 here, but exclamation marks are // rare and the extra test costs us some time. auto mask = b >= 0x24 && b <= 0x7e && b != 0x27 && b != 0x3c && b != 0x3e; #ifdef __SSE2__ if (_mm_movemask_epi8(reinterpret_cast<__m128i>(mask)) != 0xffff) { return i; } #else if (vminvq_u8(reinterpret_cast(mask)) == 0) { return i; } #endif } return i; #else // Need SIMD support (with fast reductions) for this to be efficient. return 0; #endif } template void DoAppendStringOfType(const CHAR* source, size_t length, SharedCharTypes type, CanonOutput* output) { size_t i = 0; // We only instantiate this for char, to avoid a Clang crash // (and because Append() does not support converting). if constexpr (sizeof(CHAR) == 1) { if (type == CHAR_QUERY && length >= kMinimumLengthForSIMD) { i = FindInitialQuerySafeString(source, length); output->Append(source, i); } } for (; i < length; i++) { if (static_cast(source[i]) >= 0x80) { // ReadUTFCharLossy will fill the code point with // kUnicodeReplacementCharacter when the input is invalid, which is what // we want. base_icu::UChar32 code_point; ReadUTFCharLossy(source, &i, length, &code_point); AppendUTF8EscapedValue(code_point, output); } else { // Just append the 7-bit character, possibly escaping it. unsigned char uch = static_cast(source[i]); if (!IsCharOfType(uch, type)) AppendEscapedChar(uch, output); else output->push_back(uch); } } } // This function assumes the input values are all contained in 8-bit, // although it allows any type. Returns true if input is valid, false if not. template void DoAppendInvalidNarrowString(const CHAR* spec, size_t begin, size_t end, CanonOutput* output) { for (size_t i = begin; i < end; i++) { UCHAR uch = static_cast(spec[i]); if (uch >= 0x80) { // Handle UTF-8/16 encodings. This call will correctly handle the error // case by appending the invalid character. AppendUTF8EscapedChar(spec, &i, end, output); } else if (uch <= ' ' || uch == 0x7f) { // This function is for error handling, so we escape all control // characters and spaces, but not anything else since we lack // context to do something more specific. AppendEscapedChar(static_cast(uch), output); } else { output->push_back(static_cast(uch)); } } } // Overrides one component, see the Replacements structure for // what the various combionations of source pointer and component mean. void DoOverrideComponent(const char* override_source, const Component& override_component, const char** dest, Component* dest_component) { if (override_source) { *dest = override_source; *dest_component = override_component; } } // Similar to DoOverrideComponent except that it takes a UTF-16 input and does // not actually set the output character pointer. // // The input is converted to UTF-8 at the end of the given buffer as a temporary // holding place. The component identifying the portion of the buffer used in // the |utf8_buffer| will be specified in |*dest_component|. // // This will not actually set any |dest| pointer like DoOverrideComponent // does because all of the pointers will point into the |utf8_buffer|, which // may get resized while we're overriding a subsequent component. Instead, the // caller should use the beginning of the |utf8_buffer| as the string pointer // for all components once all overrides have been prepared. bool PrepareUTF16OverrideComponent(const char16_t* override_source, const Component& override_component, CanonOutput* utf8_buffer, Component* dest_component) { bool success = true; if (override_source) { if (!override_component.is_valid()) { // Non-"valid" component (means delete), so we need to preserve that. *dest_component = Component(); } else { // Convert to UTF-8. dest_component->begin = utf8_buffer->length(); success = ConvertUTF16ToUTF8(&override_source[override_component.begin], static_cast(override_component.len), utf8_buffer); dest_component->len = utf8_buffer->length() - dest_component->begin; } } return success; } } // namespace // See the header file for this array's declaration. // clang-format off const unsigned char kSharedCharTypeTable[0x100] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x00 - 0x0f 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x10 - 0x1f 0, // 0x20 ' ' (escape spaces in queries) CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x21 ! 0, // 0x22 " 0, // 0x23 # (invalid in query since it marks the ref) CHAR_QUERY | CHAR_USERINFO, // 0x24 $ CHAR_QUERY | CHAR_USERINFO, // 0x25 % CHAR_QUERY | CHAR_USERINFO, // 0x26 & 0, // 0x27 ' (Try to prevent XSS.) CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x28 ( CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x29 ) CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x2a * CHAR_QUERY | CHAR_USERINFO, // 0x2b + CHAR_QUERY | CHAR_USERINFO, // 0x2c , CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x2d - CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_COMPONENT, // 0x2e . CHAR_QUERY, // 0x2f / CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_OCT | CHAR_COMPONENT, // 0x30 0 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_OCT | CHAR_COMPONENT, // 0x31 1 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_OCT | CHAR_COMPONENT, // 0x32 2 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_OCT | CHAR_COMPONENT, // 0x33 3 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_OCT | CHAR_COMPONENT, // 0x34 4 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_OCT | CHAR_COMPONENT, // 0x35 5 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_OCT | CHAR_COMPONENT, // 0x36 6 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_OCT | CHAR_COMPONENT, // 0x37 7 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_COMPONENT, // 0x38 8 CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_DEC | CHAR_COMPONENT, // 0x39 9 CHAR_QUERY, // 0x3a : CHAR_QUERY, // 0x3b ; 0, // 0x3c < (Try to prevent certain types of XSS.) CHAR_QUERY, // 0x3d = 0, // 0x3e > (Try to prevent certain types of XSS.) CHAR_QUERY, // 0x3f ? CHAR_QUERY, // 0x40 @ CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x41 A CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x42 B CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x43 C CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x44 D CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x45 E CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x46 F CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x47 G CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x48 H CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x49 I CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x4a J CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x4b K CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x4c L CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x4d M CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x4e N CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x4f O CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x50 P CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x51 Q CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x52 R CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x53 S CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x54 T CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x55 U CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x56 V CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x57 W CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_COMPONENT, // 0x58 X CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x59 Y CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x5a Z CHAR_QUERY, // 0x5b [ CHAR_QUERY, // 0x5c '\' CHAR_QUERY, // 0x5d ] CHAR_QUERY, // 0x5e ^ CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x5f _ CHAR_QUERY, // 0x60 ` CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x61 a CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x62 b CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x63 c CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x64 d CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x65 e CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_HEX | CHAR_COMPONENT, // 0x66 f CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x67 g CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x68 h CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x69 i CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x6a j CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x6b k CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x6c l CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x6d m CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x6e n CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x6f o CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x70 p CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x71 q CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x72 r CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x73 s CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x74 t CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x75 u CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x76 v CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x77 w CHAR_QUERY | CHAR_USERINFO | CHAR_IPV4 | CHAR_COMPONENT, // 0x78 x CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x79 y CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x7a z CHAR_QUERY, // 0x7b { CHAR_QUERY, // 0x7c | CHAR_QUERY, // 0x7d } CHAR_QUERY | CHAR_USERINFO | CHAR_COMPONENT, // 0x7e ~ 0, // 0x7f 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x80 - 0x8f 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x90 - 0x9f 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0xa0 - 0xaf 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0xb0 - 0xbf 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0xc0 - 0xcf 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0xd0 - 0xdf 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0xe0 - 0xef 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0xf0 - 0xff }; // clang-format on const char kCharToHexLookup[8] = { 0, // 0x00 - 0x1f '0', // 0x20 - 0x3f: digits 0 - 9 are 0x30 - 0x39 'A' - 10, // 0x40 - 0x5f: letters A - F are 0x41 - 0x46 'a' - 10, // 0x60 - 0x7f: letters a - f are 0x61 - 0x66 0, // 0x80 - 0x9F 0, // 0xA0 - 0xBF 0, // 0xC0 - 0xDF 0, // 0xE0 - 0xFF }; const base_icu::UChar32 kUnicodeReplacementCharacter = 0xfffd; void AppendStringOfType(const char* source, size_t length, SharedCharTypes type, CanonOutput* output) { DoAppendStringOfType(source, length, type, output); } void AppendStringOfType(const char16_t* source, size_t length, SharedCharTypes type, CanonOutput* output) { DoAppendStringOfType(source, length, type, output); } bool ReadUTFCharLossy(const char* str, size_t* begin, size_t length, base_icu::UChar32* code_point_out) { if (!base::ReadUnicodeCharacter(str, length, begin, code_point_out)) { *code_point_out = kUnicodeReplacementCharacter; return false; } return true; } bool ReadUTFCharLossy(const char16_t* str, size_t* begin, size_t length, base_icu::UChar32* code_point_out) { if (!base::ReadUnicodeCharacter(str, length, begin, code_point_out)) { *code_point_out = kUnicodeReplacementCharacter; return false; } return true; } void AppendInvalidNarrowString(const char* spec, size_t begin, size_t end, CanonOutput* output) { DoAppendInvalidNarrowString(spec, begin, end, output); } void AppendInvalidNarrowString(const char16_t* spec, size_t begin, size_t end, CanonOutput* output) { DoAppendInvalidNarrowString(spec, begin, end, output); } bool ConvertUTF16ToUTF8(const char16_t* input, size_t input_len, CanonOutput* output) { bool success = true; for (size_t i = 0; i < input_len; i++) { base_icu::UChar32 code_point; success &= ReadUTFCharLossy(input, &i, input_len, &code_point); AppendUTF8Value(code_point, output); } return success; } bool ConvertUTF8ToUTF16(const char* input, size_t input_len, CanonOutputT* output) { bool success = true; for (size_t i = 0; i < input_len; i++) { base_icu::UChar32 code_point; success &= ReadUTFCharLossy(input, &i, input_len, &code_point); AppendUTF16Value(code_point, output); } return success; } void SetupOverrideComponents(const char* base, const Replacements& repl, URLComponentSource* source, Parsed* parsed) { // Get the source and parsed structures of the things we are replacing. const URLComponentSource& repl_source = repl.sources(); const Parsed& repl_parsed = repl.components(); DoOverrideComponent(repl_source.scheme, repl_parsed.scheme, &source->scheme, &parsed->scheme); DoOverrideComponent(repl_source.username, repl_parsed.username, &source->username, &parsed->username); DoOverrideComponent(repl_source.password, repl_parsed.password, &source->password, &parsed->password); DoOverrideComponent(repl_source.host, repl_parsed.host, &source->host, &parsed->host); if (!url::IsUsingStandardCompliantNonSpecialSchemeURLParsing()) { // For backward compatibility, the following is probably required while the // flag is disabled by default. if (parsed->host.len == -1) { parsed->host.len = 0; } } DoOverrideComponent(repl_source.port, repl_parsed.port, &source->port, &parsed->port); DoOverrideComponent(repl_source.path, repl_parsed.path, &source->path, &parsed->path); DoOverrideComponent(repl_source.query, repl_parsed.query, &source->query, &parsed->query); DoOverrideComponent(repl_source.ref, repl_parsed.ref, &source->ref, &parsed->ref); } bool SetupUTF16OverrideComponents(const char* base, const Replacements& repl, CanonOutput* utf8_buffer, URLComponentSource* source, Parsed* parsed) { bool success = true; // Get the source and parsed structures of the things we are replacing. const URLComponentSource& repl_source = repl.sources(); const Parsed& repl_parsed = repl.components(); success &= PrepareUTF16OverrideComponent( repl_source.scheme, repl_parsed.scheme, utf8_buffer, &parsed->scheme); success &= PrepareUTF16OverrideComponent(repl_source.username, repl_parsed.username, utf8_buffer, &parsed->username); success &= PrepareUTF16OverrideComponent(repl_source.password, repl_parsed.password, utf8_buffer, &parsed->password); success &= PrepareUTF16OverrideComponent(repl_source.host, repl_parsed.host, utf8_buffer, &parsed->host); success &= PrepareUTF16OverrideComponent(repl_source.port, repl_parsed.port, utf8_buffer, &parsed->port); success &= PrepareUTF16OverrideComponent(repl_source.path, repl_parsed.path, utf8_buffer, &parsed->path); success &= PrepareUTF16OverrideComponent(repl_source.query, repl_parsed.query, utf8_buffer, &parsed->query); success &= PrepareUTF16OverrideComponent(repl_source.ref, repl_parsed.ref, utf8_buffer, &parsed->ref); // PrepareUTF16OverrideComponent will not have set the data pointer since the // buffer could be resized, invalidating the pointers. We set the data // pointers for affected components now that the buffer is finalized. if (repl_source.scheme) source->scheme = utf8_buffer->data(); if (repl_source.username) source->username = utf8_buffer->data(); if (repl_source.password) source->password = utf8_buffer->data(); if (repl_source.host) source->host = utf8_buffer->data(); if (repl_source.port) source->port = utf8_buffer->data(); if (repl_source.path) source->path = utf8_buffer->data(); if (repl_source.query) source->query = utf8_buffer->data(); if (repl_source.ref) source->ref = utf8_buffer->data(); return success; } #ifndef WIN32 int _itoa_s(int value, char* buffer, size_t size_in_chars, int radix) { const char* format_str; if (radix == 10) format_str = "%d"; else if (radix == 16) format_str = "%x"; else return EINVAL; int written = snprintf(buffer, size_in_chars, format_str, value); if (static_cast(written) >= size_in_chars) { // Output was truncated, or written was negative. return EINVAL; } return 0; } int _itow_s(int value, char16_t* buffer, size_t size_in_chars, int radix) { if (radix != 10) return EINVAL; // No more than 12 characters will be required for a 32-bit integer. // Add an extra byte for the terminating null. char temp[13]; int written = snprintf(temp, sizeof(temp), "%d", value); if (static_cast(written) >= size_in_chars) { // Output was truncated, or written was negative. return EINVAL; } for (int i = 0; i < written; ++i) { buffer[i] = static_cast(temp[i]); } buffer[written] = '\0'; return 0; } #endif // !WIN32 } // namespace url